KR20060087482A - Moveable support for a climbing bracket of a climbing form - Google Patents

Abstract

The movable support for the climbing bracket 10 of the climbing foam is embodied in the form of poles 22 which are integrated into the sliding bracket portion 16 of the climbing bracket 10. The lift bracket 10 consists of a wall bracket portion 18 and a sliding bracket portion 16. The lift bracket or lift brackets 10 are mounted on the anchor point of the concrete section of the structure. The pawls 22 may engage below the suspension bolt 24 of the lift rail 20 and may be disengaged from the suspension bolt 24. The pawls 22 are spring-loaded and feature recesses on one side to support the suspension bolts 24, where the suspension bolts 24 on the other side of the poles are lift rails 20. The ramp 44 is provided to pivot the poles 22 into the sliding bracket portion 16 against the spring force when displaced along the ramp 44 due to the upward manipulation.

Climbing Foam, Lift Brackets, Lift Rails, Mobility Supports, Suspension Bolts

Description

MOVEABLE SUPPORT FOR A CLIMBING BRACKET OF A CLIMBING FORM}

One embodiment of the movable support for the lifting bracket, which is implemented in the form of a pole and which can engage under suspension bolts arranged on the lifting rails, will be described below in an exemplary manner with reference to the drawings.

1 is a cross sectional view through a lift bracket according to the invention floating and guiding and supporting a lift rail and stationarily mounted on a concrete wall;

2 is a cross sectional view through a raised bracket of the present invention in which a pawl is pivoted into the raised bracket;

3 is a cross sectional view through the lifting bracket of the invention according to FIGS. 1 and 2 with the pole pivoted out of the lifting bracket and disengaged from the suspension bolt.

4 is a lift bracket with a ceiling bracket portion located on and mounted on the ceiling of a concrete section.

5 is a plan view of a lift bracket mounted on a concrete section covering a lift rail with hooks.

6 is a plan view of a lift bracket mounted on a concrete section of a wall that is open on one side so that the hooks of the lift bracket can be removed from the lift rail.

FIG. 7 is a side view of a raised bracket stationarily mounted on the wall of a concrete section, characterized by cardanic supports with respect to horizontally and vertically aligned axes. FIG.

8 is a plan view of the lift bracket of FIG.

9 is lift brackets mounted stationarily and supported on a convex wall of a concrete section with lift rails, where the lift brackets support the rail elements or consoles so that they are aligned in parallel with each other.

※ Explanation of main drawing code

14: concrete section 12: wall

10: lift bracket 16: sliding bracket part

18: wall bracket part 24: suspension bolt

20: rising rail 22: pole

26: lift cylinder 50: hook

56: safety bolt 34: hinge pin

30: articulated shaft 52: lug

44: ramp 58: pivot axis

40: lever 46: ceiling bracket portion

The present invention relates to a climbing bracket of a climbing foam mounted stationarily on a fixation point provided on a wall of a concrete section. Rails with foam for building new concrete sections mounted thereon are guided in the lifting brackets. The rails guided in the lift brackets are elevated to the desired height required with the help of a crane or self-raising device and are locked onto the structure at this height. Once the concrete section is erected, the rails are displaced from the lift bracket and displaced to the position where a new concrete segment can be erected.

The invention locks between lift brackets and lift rails that not only meet appropriate safety requirements, but also automatically adapt itself to a position that allows for seamless lift operation of scaffold units or lift rails connected to lift rails. It is based on the goal of simplifying the climbing operation of the climbing foam by enabling the device.

This goal is achieved by a movable support for the lift bracket of the climbing foam provided on the sliding bracket portion of the lift bracket and engaged and supported under the first suspension bolt of the lift rail in the first position of the support, which is supported by the second support. Permits displacement of the ascending rail from the suspension bolt to the raised or lowered position along the lift brackets due to disengagement of the support from the suspension bolts, the support being further adapted to support the second of the lift rails arranged below or above the first suspension bolt at Engage under the suspension bolts.

The support of the present invention thus provides a significant advantage that it is movably integrated into the lift bracket and in this respect no separate structural modifications are required on the lift rails. The lift rails engage into the supports of the lift bracket with suspension bolts provided along and securely supported therein within each other within a predetermined distance from each other. The supports engage once again under the suspension bolts of the lift rails when the lift rails are displaced from the suspension bolts as they are displaced along the already established concrete section and reach the new position of the lift rails on the structure to be built. A new concrete section is then erected at the new position of the lift rails with the help of foam supported on the lift rails. Once a new concrete section is built, the rising rails are displaced into a position where a new concrete section can be built. For this purpose, the lifting bracket is mounted on the anchor point provided on the newly set concrete section and then supported. Displacement or lift operation can be implemented with the aid of a crane or lifting cylinder system. In a preferred embodiment of the invention, the support is implemented in the form of a pole. The pawl can support and guide the suspension bolt in a corresponding recess on the pawl surface, which pawl can be disengaged from the suspension bolt by, for example, a pivot mechanism. The pawl can be spring-loaded to always be pressed into a specific position under the influence of the spring.

It is advantageous to provide two poles on the sliding bracket. In this case, the two pawls are spaced apart from each other and engage under the suspension bolt in two positions, distributing the bending load acting on the suspension bolt.

If the poles or poles in the sliding bracket can be spring loaded and arranged so that they can pivot about the pivot point in the sliding bracket, the poles can pivot into the sliding bracket portion as opposed to the force of the spring when the lift rails must be displaced along the wall. have. In this respect, it is advantageous to provide a ramp on one side of the poles or poles which then causes the upwardly displaced suspension bolts to pivot the poles or poles into the sliding bracket portion as opposed to the force of the spring. Once the suspension bolt has moved past the ramp, the poles or poles can automatically pivot out of the sliding bracket portion, ie into a position where the pole can once again serve as a support for the suspension bolt of the lift rail.

In another embodiment of the invention, the lever coupled with the pawl or pawls protrudes above the sliding bracket portion, where the pawl or pawls can be pivoted about the pivot point by the lever. If the poles are required to disengage from the suspension bolts when the rising rails are lowered or system modification is performed, the lever in the sliding bracket portion makes it possible to manually pivot the poles into the sliding bracket portion.

The sliding bracket portion is pivotally connected to the wall bracket portion with the aid of a removable hinge pin such that the sliding bracket portion can be aligned with the wall bracket portion under load. The hinge pin can also be removed so that the sliding bracket portion can be very easily separated from the wall bracket portion.

The sliding bracket portions of the lift bracket guide the lift rails during the lift operation in such a way that they can always be displaced in a controlled manner at a predetermined distance from the wall surface of the structure.

Embodiments of the invention have been illustrated in a very schematic manner in the drawings and are not drawn to scale.

Identical functional elements have been designated by approximately identical reference numerals in the drawings described below. These functional elements may be objectively designed in many different ways.

1 shows a partial side cross-sectional view of a lift bracket 10 mounted stationarily on a fixation point on the wall surface 12 of a concrete section 14. The lift bracket 10 is composed of a sliding bracket portion 16 and a wall bracket portion 18. The lift rail 20 is carried out and guided laterally by the pawl 22 of the sliding bracket portion 16 where the pawl 22 engages below the suspension bolt 24 of the lift rail 20. The pole 22 is illustrated at the maximum pivot angle, and the objectively designed alternation in the sliding bracket portion 16 prevents the pole 22 from further pivoting clockwise.

The lift cylinder 26 is attached to the sliding bracket portion 16 of the lift bracket 10. Only the bottom portion of the lift cylinder 26 is shown, where the bottom portion is coupled to the articulated shaft 30 of the lift bracket 10 by a housing 28 for attaching the lift cylinder 26. The safety bolt 32 secures the housing 28 on the articulated shaft 30 without limiting the pivot range of the lift cylinder 26 relative to the articulated shaft 30. The lift cylinder 26 can be removed from the articulated shaft 30 by releasing the safety bolt 32 from the articulated shaft 30 against spring force. The housing 28 of the lift cylinder 26 is supported on the housing wall of the sliding bracket portion 16 by a rubbery or viscous element 33.

The sliding bracket portion 16 is articulatedly connected to the wall bracket portion 18 by horizontally aligned removable hinge pins 34. The sliding bracket portion 16 may pivot with respect to the wall bracket portion 18 with respect to the hinge pin 34.

The pawl 22 may pivot counterclockwise within the sliding bracket portion 16 relative to the pivot point 36 against the spring 38 force.

If the pawl 22 is not loaded by the suspension bolts 24 of the rising rail 20, the pawl 22 is passive into the sliding bracket portion 16 against the spring 38 force with the aid of the lever 40. Can be pivoted. This is required in all cases where the lift rail 20 must be displaced downward relative to the lift bracket 10 arranged stationary.

Only a portion of the concrete section 14, the lift rail 20 and the lift cylinder 26 are illustrated in this figure.

FIG. 2 shows a snapshot of the rise rail 20 when it is displaced upward along the wall surface 12 of the concrete section 14 in the direction of the arrow 42 by the rise cylinder 26. The piston of the lift cylinder 26 is extended in order to implement this lift operation of the lift rail 20 in the direction of the arrow 42, where the free end of the piston also has suspension bolts 24 of the lift rail 20. ) Features a pawl to engage and support from below.

When the lift rail 20 is displaced in the direction of the arrow 42 by the lift cylinder 26, the suspension bolt 24 of the lift rail 20 presses against the ramp 44 of the pole 22 and the spring ( 38) Pivot the pole about the pivot point 36 against the force. In this case, the pawl 22 is pivoted into the sliding bracket portion 16 of the lift bracket 10.

3 shows the lifting brackets of FIGS. 1 and 2 above the wall 12 of the concrete section 14 as the pole 22 pivots back to its initial position with respect to the pivot point 36 under the influence of the spring 38 ( 10) is shown. The lift rail 20 is further displaced in the direction of the arrow 42 by the lift cylinder 26 so that the suspension bolt 24 can escape the pawl 22 and the pawl pivots back to its initial position.

When the lift cylinder 26 is retracted, the suspension bolt 24 is lowered toward the pole 22 and the lift bracket 10 is raised rail 20 over the wall 12 of the concrete section 14 at the position illustrated in the figure. Support).

4 shows a side view of a modified lifting bracket 10 consisting of a sliding bracket portion 16 and a ceiling bracket portion 46. The ceiling bracket portion 46 is located on the ceiling 48 of the concrete section 14 and mounted stationarily. The sliding bracket portion 16 is articulatedly connected to the ceiling bracket portion 46 by a hinge pin 34. When the hinge pin 34 is removed from the ceiling bracket portion 46, the sliding bracket portion 16 with the hook 50 can be separated from the ceiling bracket portion 46. The pawls or poles of the sliding bracket portion 16 which are respectively engaged under the suspension bolts of the inserted lift rail and which can be pivoted by the suspension bolt during the lift operation are covered by the hooks 50. The lever 40 shown in the figure is coupled to the pawl in the sliding bracket portion 16 where the lever 40 can manually pivot the pawl or poles in the sliding bracket portion 16.

Lugs 52 illustrated on the sliding bracket portion 16 carry the articulated shaft 30. The lift cylinder may be attached to the articulated shaft 30.

FIG. 5 shows a top view of the lifting bracket 10 with the wall bracket portion 18 and the sliding bracket portion 16 mounted stationarily on the wall surface 12 of the concrete section 14. The sliding bracket portion 16 is articulatedly connected to the wall bracket portion 18 by a hinge pin 34. The hooks 50 cover the legs of the U-shaped profile of the lift rail 20 and bear the lift rail 20 on the wall 12 in a guided manner. The poles 22 of the lift bracket portion 16 engage below the suspension bolts 24 on one side of the lift rail 20. The articulated shaft is arranged on the sliding bracket portion 16 to attach the lift cylinder. Only half of the hooks 50 can be pivoted about the shaft 54 after the safety bolt 56 has been removed from its socket to prevent possible pivotal movement of the left hook 50.

FIG. 6 shows the lifting bracket 10 of FIG. 5 with a hook 50 pivoted to an open position on one side.

One hook 50 of the sliding bracket portion 16 if it should be possible to mount and remove the lifting bracket 10 from / on the wall 12 of the concrete section 14 in the presence of the lifting rail 20. Can be pivoted to the open position after the safety bolt 56 is disengaged from the rigid wall concrete of the sliding bracket portion 16 and pulled out of the opening in the hook 50. Once the engagement of the locked arrangement is released, the hook 50 can pivot about the axis 54. Once the hook 50 is pivoted to the open position, the safety bolt 56 may be reinserted into the locking position of the hook 50 to ensure that the hook remains in the state illustrated in the figure. The sliding bracket portion 16 subsequently removes the hinge pin 34 between the sliding bracket portion 16 and the wall bracket portion 18, ie by pulling the hinge pin out of the common support in the direction of the arrow 57. Can be removed from the lift rail 20. If desired, the wall bracket portion 18 can then be separated and removed from the fixation point above the wall 12.

FIG. 7 shows a side view of the lift bracket 10 supported cardically on the wall 12 of the concrete section 14. The sliding bracket portion 16 is connected in a horizontal articulated manner to the wall bracket portion 18 by a hinge pin 34. This wall bracket portion 18 also has a vertically aligned pivot axis 58 in comparison to the raised brackets of FIGS. 1 to 6, with which the wall bracket portion 18 is a sliding bracket portion 16 if required. Can be pivoted together. Lug 52 carrying articulated shaft 30 is arranged on sliding bracket portion 16. The hooks 50 cover the poles arranged between the hooks 50.

FIG. 8 shows a top view of the cardanally supported lift bracket 10 according to FIG. 7. The lift bracket 10 can be pivoted about a horizontally aligned axis and a vertically aligned axis 58 formed stationary on the wall 12 of the concrete section 14 and formed by the hinge pin 34. . The sliding bracket portion 16 is pivotally supported on the wall bracket portion 18 with the help of the hinge pin 34, which wall bracket portion 18 can pivot itself about the axis 58. The hook 50 is pivotably supported about the shaft 54 where the safety bolt 56 produces a rigid hooked connection between the sliding bracket portion 16 and the pivot hook 50 in the working state. Pivot poles 22 are arranged between the hooks 50 in the sliding bracket portion 16.

9 shows a top view of the concrete section 14 implemented in a circular manner. Lift brackets 10 for respectively guiding the lift rails 20 between the hooks 50 are mounted on fixing points provided on the concrete section 14 and the lift rails 20 are lift brackets 10. Is supported in place by means of a pawl arranged in FIG. 2, ie on the suspension bolts 24 provided in the rising rails 20.

The consoles or rails 60 mounted above the lift rails 20 are always aligned parallel to one another on the concrete section 14 by means of lift brackets 10 supported in a cardan manner. If the consoles or rails 60 are arranged so that they are always parallel to each other at different curvatures of the concrete section, the foam carriage may be displaced above the rails 60 towards the concrete section 14 and away from the concrete section 14. Can be. The vertically aligned axes 58 are such that the consoles 60 or the rails extend parallel to one another, ie the lifting brackets 10 to the rising rails 20 irrespective of the radius of curvature of the concrete section 14. ) Is always aligned.

The movable support for the climbing bracket 10 of the climbing foam is embodied in the form of poles 22 which are integrated into the sliding bracket portion 16 of the climbing bracket 10. The lift bracket 10 consists of a wall bracket portion 18 and a sliding bracket portion 16. The lift bracket or lift brackets 10 are mounted on the anchor point of the concrete section of the structure. The pawls 22 may engage below the suspension bolt 24 of the lift rail 20 and may be disengaged from the suspension bolt 24. The poles 22 are spring-loaded and feature recesses on one side to support the suspension bolts 24, where the suspension bolts 24 on the other side of the poles are driven by the lift operation of the lift rails 20. The lamp 44 is provided to pivot the poles 22 into the sliding bracket portion 16 against the spring force due to the displacement along the lamp 44.

Claims (8)

Climbing bracket 10 of the climbing foam provided on the sliding bracket portion 16 of the lift bracket 10 and engaged and supported under the first suspension bolt 24 of the lift rail 20 in the first position of the support 22. ) Is a movable support for lifting and lowering the lifting rail 20 along the lifting bracket 10 due to the disengagement of the support 22 from the suspension bolt 24 in a second position. And the support is engaged under the second suspension bolt (24) of the lift rail (20) arranged below or above the first suspension bolt (24) in a third position. 2. A movable support for a lift bracket according to claim 1, wherein said support consists of a pole (22). 3. The movable support of claim 2, wherein two poles (22) are provided in the sliding bracket portion (16). The lift according to claim 2 or 3, characterized in that the pawl (22) or pawls (22) are arranged in the raised bracket portion (16) in a spring-loaded manner so that they can be pivoted about the pivot point (36). Mobility support for the bracket. 5. The movable support of claim 2, wherein one side of the poles (22) or poles (22) is a ramp (44). 6. The lever (40) according to claim 2, wherein the lever (40) is coupled to the pawl (22) or the pawls (22) and protrudes above the sliding bracket portion (16), wherein the lever (40) Movable support for lift bracket, characterized in that the pole or poles (22) can be pivoted with respect to the pivot point (36). The lifting bracket according to claim 2, wherein the sliding bracket portion 16 is pivotally connected to the wall bracket portion 18 by a horizontally aligned hinge pin 34. Mobility support. 8. The movable support according to any one of claims 2 to 7, wherein the sliding bracket portion (16) guides the lift rail during a lift operation.

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